NaCl + CH3OH + H2O Mixture: Investigation Using the Pitzer and the

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NaCl + CH3OH + H2O Mixture: Investigation Using the Pitzer and the Modified Pitzer Approaches To Describe the Binary and Ternary Ion− Nonelectrolyte Interactions Farzad Deyhimi* and Maryam Abedi Department of Chemistry, Shahid Beheshti University, G.C., Evin-Tehran 1983963113, Iran ABSTRACT: In this work, NaCl electrolyte in different mass fractions of CH3OH (x) + H2O (1 − x) mixed solvents (where x = 0.10, 0.20, 0.30, 0.40, and 0.50) were investigated by the Pitzer and the modified Pitzer equations. Since in mixed solvent electrolyte system the interactions of the ion−nonelectrolyte are absent in the Pitzer equation, the modified Pitzer equations were used for the determination of the binary and ternary ion− nonelectrolyte interaction parameters. The experimental data were obtained by using a galvanic cell using an Na+-glass membrane and Ag/AgCl electrodes for collecting the potentiometric data with a series of electrolyte solutions, at (298.15 ± 0.05) K.



the Pitzer equation was also performed by Koh et al.,9 Boukhalfa and Méniai,10 and Yan et al.11 Therefore, because of the unavailability of the Pitzer coefficients and the related data at relatively high concentrations for CH3OH mass fractions x = 0.10, 0.30, and 0.50 in H2O, we have also determined in this work the Pitzer ion-interaction parameters β(0), β(1), and Cφ for NaCl at these CH3OH mass fractions, along with the binary and ternary ion−nonelectrolyte interaction parameters based on the modified Pitzer equations.

INTRODUCTION The determination of the thermodynamic properties of electrolytes such as solvent osmotic coefficients, activity coefficients, and excess Gibbs free energies in aqueous and in mixed solutions is necessary for understanding the nature of various ionic interactions and also for handling of various industrial and environmental processes such as desalination, chemical separation, marine chemistry, geology, and environmental problems. The use of the ion-selective electrodes (ISEs) proved to be an efficient method for the determination of the activity coefficients in electrolyte systems. For many years, we have used in our laboratory glass membrane1,2 and solvent polymeric membrane ISEs for the determination of mean activity coefficients of electrolytes in aqueous3,4 and mixed solvents.5,6 In this work, the modified Pitzer equations were used for the investigation of NaCl electrolytes in different mass fractions of CH3OH (x) in H2O (1 − x), where x = 0.10, 0.20, 0.30, 0.40, and 0.50. The experimental data were obtained by using a galvanic cell containing an Na+-glass membrane electrode and an Ag/AgCl electrode for collecting the potentiometric data over the total electrolyte molality, ranging from about 0.001 mol·kg−1 up to 3.3 mol·kg−1, at (298.15 ± 0.05) K. The modified Pitzer equations permit the determination of the binary and ternary ion−nonelectrolyte interaction parameters which are absent in the Pitzer equation. The available literature data for this mixture, specifically for the CH3OH mass fractions x = 0.10, 0.30, and 0.50 in H2O,7,8 are limited up to the molality of 0.2 mol·kg−1.7,8 Because of the used low concentration range of electrolytes in these investigations, the triple interaction Pitzer parameters were neglected by these authors. The related experimental data at high concentrations were reported by Yan et al.11 and Basili et al.12 for CH3OH mass fractions x = 0.20, 0.40, 0.60, 0.80 and 1.00 in H2O. In addition, modeling NaCl electrolyte in CH3OH + H2O mixed solvent by © 2011 American Chemical Society



EXPERIMENTAL SECTION Materials. Methanol of analytical grade (purity >0.995) from Fluka was used as received. The analytical grade NaCl salts (mass percent fraction >0.995) were obtained from Fluka. Each time, prior to use, the analytical grade NaCl salt (mass percent fraction >0.995), from Fluka, was dried overnight in an oven (at 110 °C). All primary stock solutions were prepared by weight using a Sartorius CPA225d electronic balance with a resolution of 0.01 mg in doubly distilled water. The Na+-glass membrane electrode (model 6.0501.100) was obtained from Metrohm, and Ag|AgCl wires, prepared essentially as described elsewhere by electrolysis,13 were used as internal reference electrodes. The lifetime of Ag/AgCl electrodes is limited and influenced by many effects such as the depletion of Ag, formation of complexes, and continuous dissolution of the AgCl layer and its oxidation due to the presence of trace of impurities and free dissolved O2, respectively. The decreased operational performance of Ag/AgCl electrodes with increasing electrolyte concentration affects also its resulting potential.13 Therefore, in our work, pairs of Ag/AgCl electrodes were used to check against each other to ensure equivalent response. Under normal Received: August 2, 2011 Accepted: December 14, 2011 Published: December 29, 2011 324

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where the constants εo, k, NA, D, and ρA are the vacuum permittivity, Boltzmann constant, Avogadro constant, dielectric constant, and density of the mixed solvent, respectively. Modified Pitzer Equation. To improve the fitting of experimental data containing polar nonelectrolyte, Esteso and co-workers15−17 performed some modifications to the original Pitzer equation to include the dependence of the binary interaction parameters (containing the nonelectrolyte) on the ionic strength and the ion−nonelectrolyte interactions on the nonelectrolyte concentration. For an aqueous electrolyte system containing MX electrolyte (B) and polar nonelectrolyte (A), the modified Pitzer equation for the activity coefficient of the electrolyte can be written as:

usage, in our experimental conditions, each Ag/AgCl electrode lasted about 8 weeks. Potentiometric Measurement and Data Acquisition Process. The experimental cell potentials were recorded using Metrohm ion-meter (model 619) with a high input impedance (>1 TΩ) connected to a Topward multimeter equipped with a GPIB interface Bus option (model 1304, Taiwan, Korea). The output of the multimeter was finally connected to a personal computer (Samsung, 386/32 MHz processor) via the GPIB interface card (IEEE488, Keithley) for data acquisition and processing. The reading potential accuracy of instrumental setup was 0.1 mV. A laboratory written Basic program combined with Microsoft Excel (XP-Office 2007) software were also used for data acquisition and calculations. All measurements were performed under stirring conditions at a fixed temperature employing a double-wall container enabling the circulation of thermostatted water from a bath (Julabo thermostat MF12, Germany) with temperature kept constant at (298.15 ± 0.05) K. The electrodes and a glass thermometer were immersed in the solution through a lid, preventing solvent evaporation. In each mixed solvent system and for each molality, data acquisitions were performed at every 4 s interval and during 20 min (for concentrated solutions) to 60 min (for dilute solutions). From data processing, a resulting final potential mean value with a standard deviation never exceeding 0.1 mV during 1 min was accepted for each concentration.

⎛γ ⎞ ⎛γ ⎞ ⎜ B⎟ ⎟ ln⎜⎜ MX o ⎟ = ln⎜ o ⎟ γ ⎝ MX ⎠ ⎝ γB ⎠ 2 = χ mA + |zMzX|χ′BA mA mB νB BA 2 + νMν XξABBmA mB + ωAABmA 2 νB

In eq 6, the ion−nonelectrolyte binary interaction parameter, χ, and its derivative, χ′, are expressed as16,17

⎧ 2 ⎫ (1,0) (1,1) ⎬ ⎨ χBA = χ(0) + χ + χ ( m ) BA BA BA A 2 αoI ⎭ ⎩



METHOD Pitzer Equation. For a Mν+Xν− single electrolyte, the Pitzer equation is written as14 ⎛ 2ν ν ⎞ ln γ± = |z+z−|f + m⎜ + − ⎟Bγ ⎝ ν ⎠ ⎛ 2(ν ν )3/2 ⎞ ⎟⎟Cγ + m2⎜⎜ + − ν ⎝ ⎠ γ

(1)

f

⎡ ⎤ I / m0 2 0 ⎥ ⎢ = −A ϕ + ln(1 + b I /m ) ⎢⎣ 1 + b I /m0 ⎥⎦ b

Bγ = 2β(0) +

2β(1) 2

0

α (I / m )

γ

C = (3/2)C

(2)

[1 − exp( −α I /m0 )

(1 + α I /m0 − (1/2)α 2(I /m0))] ϕ

(3)







[1 − (1 + αoI 0.5)exp( − αoI 0.5)]

(7)

2 ⎡ (1,1) χ′BA = (χ(1,0) −1+ BA + χ BA mA ) 2 ⎢ αo I ⎣ ⎛ ⎞⎤ 1 0.5 ⎜1 + α I + αo2I ⎟⎥exp( − αoI 0.5)] o ⎝ ⎠⎦ 2

(8)

Ag|AgCl|NaCl(mB = I ), MeOH(mA )|Na+(ISE)

(4)

Ag|AgCl|NaCl(mB = I )|Na+(ISE)

γ± is the molality-scale mean ionic activity coefficient of the electrolyte Mν+Xν−; Z, the charge number of ions; ν = ν+ + ν−, the number of ions dissociated in one unit electrolyte formula; m, the molality of electrolyte (mol·kg−1); I, the ionic strength on a molality scale; β(0), β(1), and Cϕ are the parameters of the Pitzer equation; b = 1.2 kg1/2·mol−1/2 and α = 2 kg1/2·mol−1/2. Aϕ is the Debye−Hückel coefficient for the osmotic coefficient defined as

⎛ ⎞3/2 1 e2 ⎟ A ϕ = (2πNA ρA )1/2 ⎜ 3 ⎝ 4πεoDkT ⎠



ξ and ω are the ternary interaction parameters of nonelectrolyte−ion−ion and nonelectrolyte−nonelectrolyte−ion, respectively. In principle, ξ and ω depend on the ionic strength of the solution, but their values are small, and their dependence on the ionic strength of the solution is not taken into account. χ(0), χ(1,0), and χ(1,1) are the adjustable parameters; αo = 2 kg1/2·mol−1/2 is a fixed value, and I is the ionic strength. Potentiometric Measurements. The following galvanic cells containing an Na+-glass membrane electrode and an Ag/ AgCl electrode were used for collecting the potentiometric data and for elimination of the asymmetry potential18

where γ

(6)

(I) (II)

The mean activity coefficients of NaCl in the mixtures were then determined at T/K = 298.15 by combining the potentiometric response of the cells I and II represented by the Nernst relation

⎛γ ⎞ ΔE = E(I) − E(II) = 2s ln⎜⎜ Bo ⎟⎟ ⎝ γB ⎠

(9)

where s = (RT/F) is the Nernstian slope and in which the symbols have their usual meanings. γB and γBo are the mean activity coefficients of NaCl in the mixtures, in the presence and

(5) 325

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Table 1. Experimental Mean Activity Coefficients (γ±) of NaCl Electrolyte in Different Mass Fractions of CH3OH (x = 0.10, 0.20, 0.30, 0.40, and 0.50) in Water and the Corresponding Potentiometric Responses (ΔE/mV) at 298.15 K x = 0.10 NaCl/mol·kg−1

γ±(NaCl)

0.0010 0.0025 0.0050 0.0075 0.0100 0.0250 0.0500 0.0750 0.1000 0.1500 0.2000 0.2500 0.5000 0.7500 1.0000 1.2500 1.5000 1.7500 2.0000 2.5000 2.7500 2.9625 3.1433 3.2977

0.9613 0.9413 0.9203 0.9053 0.8932 0.8465 0.8033 0.7754 0.7548 0.7252 0.7043 0.6884 0.6435 0.6234 0.6140 0.6107 0.6117 0.6159 0.6226 0.6424 0.6551 0.6672 0.6784 0.6887

x = 0.20 ΔE/mV −115.7 −69.1 −34.3 −14.2 0.0 44.7 78.0 97.2 110.7 129.6 143.0 153.4 185.9 205.2 219.3 230.6 240.2 248.5 256.0 269.2 275.2 278.0 283.9 287.2 x = 0.40

γ±(NaCl)

ΔE/mV

NaCl/mol·kg−1

γ±(NaCl)

ΔE/mV

0.0005 0.0010 0.0024 0.0048 0.0095 0.0239 0.0477 0.0716 0.0954 0.2385 0.4766 0.7145 0.9520 1.1892 1.4261 1.8989 2.1348 2.2762 2.3234

0.9677 0.9564 0.9352 0.9126 0.8832 0.8321 0.7841 0.7528 0.7295 0.6535 0.6017 0.5784 0.5673 0.5632 0.5638 0.5743 0.5832 0.5894 0.5917

−149.7 −114.6 −68.6 −34.0 0.1 44.4 77.1 95.9 109.2 150.8 182.4 201.2 215.1 226.2 235.6 251.4 258.3 262.1 263.4

0.0005 0.0010 0.0025 0.0050 0.0100 0.0250 0.0500 0.0750 0.1000 0.2500 0.5000 0.7500 1.0000 1.2500 1.5000 2.0000 2.2500 2.4500 2.5000 2.6500

0.9629 0.9504 0.9265 0.9014 0.8687 0.8121 0.7592 0.7249 0.6995 0.6171 0.5616 0.5371 0.5259 0.5222 0.5237 0.5371 0.5480 0.5583 0.5611 0.5701

−148.7 −113.8 −67.9 −33.6 0.2 43.9 76.0 94.5 107.5 148.2 179.0 197.5 211.3 222.4 231.9 248.0 255.1 260.4 261.7 265.5

x = 0.50

NaCl/mol·kg−1

γ±(NaCl)

ΔE/mV

NaCl/mol·kg−1

γ±(NaCl)

ΔE/mV

0.0005 0.0010 0.0026 0.0052 0.0103 0.0258 0.0515 0.0773 0.1031 0.2578 0.5159 0.7742 1.0327 1.2915 1.5505

0.9585 0.9444 0.9178 0.8900 0.8537 0.7912 0.7330 0.6953 0.6675 0.5772 0.5155 0.4868 0.4720 0.4648 0.4627

−149.3 −114.1 −67.8 −33.5 0.3 43.9 75.9 94.2 107.0 147.1 177.2 195.3 208.6 219.5 228.7

0.0005 0.0008 0.0010 0.0025 0.0051 0.0076 0.0101 0.0253 0.0505 0.0758 0.1011 0.1265 0.2533 0.5080 0.7641 1.0217 1.2807

0.9057 0.8975 0.8910 0.8634 0.8346 0.8139 0.7973 0.7335 0.6744 0.6364 0.6084 0.5863 0.5178 0.4551 0.4248 0.4078 0.3981

−235.4 −213.0 −197.7 −148.9 −112.7 −91.8 −77.1 −31.3 2.3 21.4 34.8 45.0 76.4 107.5 126.1 139.8 150.9

relatively high concentrations for CH3OH mass fractions x = 0.10, 0.30, and 0.50 in H2O (not reported previously) for this mixture and the corresponding standard deviation values (σ = rmsd)

in the absence of nonelectrolyte at same ionic strengths, respectively.



x = 0.30

NaCl/mol·kg−1

RESULTS

The values γBo for the pure NaCl were calculated at the appropriate ionic strengths used in this work from the available Pitzer ion-interaction parameters for the pure NaCl.19 The obtained experimental mean activity coefficients of NaCl electrolyte in different mass fractions (x) of CH3OH in water and the corresponding potentiometric responses, at T/K = 298.15, are presented in Table 1. Table 2 shows the resulting Pitzer ion-interaction parameters β(0), β(1), and Cφ and particularly the related parameters at

2 ⎞1/2 ⎛ ∑n (E i = 1 i ,exp − Ei ,calc) ⎟ ⎜ σ=⎜ ⎟ n−1 ⎝ ⎠

(10)

where E is the emf (electromotive force) and n is the number of experimental data points. The reported Pitzer parameters values9−11 were also included in Table 2 for comparison. The used values of Aϕ, dielectric 326

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Table 2. Comparison of Pitzer Ion-Interaction Parameters β(0), β(1), and Cφ for NaCl in Different Mass Fractions of CH3OH (x) in Watera MeOH x 0 0.1 0.2

0.3 0.4

0.5

β(0)

β(1) −1

kg·mol

C(φ)

mmax

−1

kg ·mol−2

mol·kg−1

σ

0.2639 0.2198 0.312 0.1063 0.37799 0.3278 0.0821 0.0846 0.468 0.0685 0.524 0.2752 0.2785 0.1206 0.655

0.0011 0.0023

6.144 3.298 0.2 2.323 0.2 3.67 4 2.65 0.2 1.55 0.2 1.68 2 1.304 0.2

1.323·10−5 2.35·10−1b 7.3·10−4 3.64·10−1b 2.07·10−3 1.9.10−1 1.97·10−3c 6.64·10−1b 2.7·10−3 3.52·10−1b 1.09·10−3 1.5.10−1 3.81·10−3c 3.89·10−1b 2.89·10−3

2

kg·mol

0.0771 0.08 0.068 0.0966 0.046 0.0985 0.1067 0.1036 0.037 0.1015 0.062 0.1349 0.1136 0.0999 0.014

0.0015 −0.0028 −0.0053 0.0028

−0.0146

ref 19 this 9 this 9 11 10 this 9 this 9 11 10 this 9

work work

work work

work

mmax and σ are the maximum molality and the corresponding root-mean-squared deviation for each series, respectively, at 298.15 K. bStandard deviation values (rmsd) calculated using E/mV values. cPitzer parameters calculated by Boukhalfa and Méniai10 using the experimental data of Feakins and Voice8 and Basili et al.12 a

constant (D), and density (ρ A ) for different solvent compositions9 are also presented in Table 3. Table 3. Solvent Density (ρA), Dielectric Constant (D), and Debye−Hückel Coefficient for the Osmotic Coefficient Values (Aϕ) in Different Mass Fractions of CH3OH (x) in water, at 298.15 K, Taken from the Literature9 CH3OH

ρA/g·mL−1

D



0 0.10 0.20 0.30 0.40 0.50

0.9971 0.9799 0.9645 0.9481 0.9319 0.9125

78.30 74.20 70.00 65.41 60.94 56.30

0.3921 0.4214 0.4562 0.5008 0.5521 0.6152

Figure.1 shows the obtained experimental mean activity coefficients of NaCl electrolyte versus molality in different mass fractions (x) of CH3OH in water. The only available experimental data at relatively high concentrations that could be used for comparison are those of Yan et al.11 and Basili et al.12 at mass fractions x = 0.20 and 0.40 of CH3OH in water which were also included in Figure 1 for comparison. As can be seen, only the data of Basili et al.12 at mass fractions x = 0.20 of CH3OH in water compare well with our results, while there are inconsistencies between our results and those of Yan et al.11 and Basili et al.12 at x = 0.40 mass fraction of CH3OH. It has to be noted that the data of Yan et al.11 and Basili et al.,12 at mass fractions of x = 0.20 of CH3OH in water diverge also between each other. The inconsistencies between our results and those of Yan et al.11 both at x = 0.20 and x = 0.40 and Basili et al.12 at x = 0.40 mass fractions of CH3OH appear also at low concentrations (see Figure 2). However, as shown in Figure 2, at lower concentrations, the general trends of our data compare well with those of Åkerlöf7 at all investigated mass fractions of CH3OH and also with those of Basili et al.12 at x = 0.20. Table 4 shows the binary (ion−CH3OH) and triple (ion− ion−CH3OH, the ion−CH3OH−CH3OH) interaction param-

Figure 1. Experimental mean activity coefficients of NaCl electrolyte versus molality in different mass fractions (x) of CH3OH in water, with x = 0, 0.10, 0.20, 0.30, 0.40, and 0.50. The reported data of Yan et al.11 and Basili et al.12 at mass fractions of x = 0.20 and 0.40 are also included in this figure. □, mean activity coefficients of NaCl in water calculated using Pitzer parameters of Marshall et al.;19 ●, mean activity coefficients of NaCl obtained in this work; red ∗, mean activity coefficients of NaCl taken from Yan et al.;11 and green ○, data taken from Basili et al.12

eter values of the modified Pitzer equations. From the comparison of the σ (rmsd) in the presence and in the absence of the ion−CH3OH−CH3OH triple interactions it can be concluded that the triple interactions are not negligible. The binary parameters xAB(0) do not show any significant variation in the different mass fractions of CH3OH, while xAB(1,1) shows a decreasing trend with the increasing mass fraction of CH3OH. The relatively large and negative values of the ion−alcohol binary interaction xAB(1,0) was interpreted as responsible for some association phenomenon between the Na+ or Cl− ions and the CH3OH in these mixtures.16,17 327

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parameters xAB(0) do not present any significant variation in different mass fractions series of CH3OH, while xAB(1,1) shows a decreasing trend with increasing CH3OH mass fraction. Finally, the relatively large and negative values of the ion−alcohol binary interaction xAB(1,0) was interpreted as responsible for some association phenomenon between the Na+ or Cl− ions and the CH3OH in these mixtures.16,17 The modified Pitzer approach permitted the determination of various binary ion−solvent and ternary ion−ion−solvent interaction coefficients (not reported previously) which represent complementary data to the Pitzer binary and ternary ion−ion interaction coefficients. A comparison of the two models shows that the modified Pitzer approach presents a better fit of the mean activity coefficients for NaCl in MeOH− H2O mixtures based on the resulting roots of mean square deviation of their fits.

Figure 2. Obtained experimental mean activity coefficients of NaCl electrolyte versus molality, at low concentrations, in different mass fractions (x) of CH3OH in water, with x = 0.10, 0.20, 0.30, 0.40, and 0.50, compared to the corresponding results reported in literature. ●, mean activity coefficients of NaCl obtained in this work; red ∗, mean activity coefficients of NaCl taken from Yan et al.11 with x = 0.20 and 0.40; purple ○, data taken from Basili et al.12 with x = 0.20 and 0.40; and green △, data taken from Åkerlöf7 with x = 0.10, 0.20, 0.30, 0.40, and 0.50.





AUTHOR INFORMATION

Corresponding Author

*Tel./fax: +98 21 22431661. E-mail address: f-deyhimi@sbu.ac. ir. Funding

The authors acknowledge and are grateful to the Research VicePresidency of Shahid Beheshti University for financial support.

CONCLUSION



The Pitzer and the modified Pitzer equations were used in this work for the investigation of NaCl electrolytes in different mass fractions (x) of CH3OH in H2O, where x = 0.10, 0.20, 0.30, 0.40, and 0.50 and in the molality range of (0.001 to 3.3) mol·kg−1. A galvanic cell containing an Na+-glass membrane and Ag/AgCl electrodes were also used for collecting the potentiometric experimental data at (298.15) K. The Pitzer ion-interaction parameters β(0), β(1), and Cφ (not previously reported) for NaCl in different mass fractions x = 0.10, 0.20, 0.30, 0.40, and 0.50 of CH3OH in water at relatively high concentrations were determined, and the results were reported. The available literature data, specifically for the CH3OH mass fractions x = 0.10, 0.30, and 0.50 in H2O, are mainly limited up to the molality of 0.2 mol·kg−1, in which the triple interaction Pitzer parameter Cφ are neglected. The obtained experimental data at relatively high concentrations at mass fractions x = 0.20 and 0.40 of CH3OH in water were compared to those of Yan et al.11 and Basili et al.12 and at lower concentrations also to those of Åkerlöf7 at x = 0.10, 0.20, 0.30, 0.40, and 0.50. Using the modified Pitzer equations,15−17 the binary (χ(0), (1,0) χ , and χ(1,1)) and ternary ion−nonelectrolyte interaction parameters (ξ and ω) were determined for this mixture for different mass fractions of CH3OH in H2O. The results showed that the triple interactions are not negligible and should be taken into account. The results showed also that the binary

REFERENCES

(1) Deyhimi, F.; Ebrahimi, A.; Roohi, H.; Koochaki, K. Determination of Activity Coefficients, Osmotic Coefficients, and Excess Gibbs Free Energies of HCl in N,N-Dimethylformamide-Water Mixed Solvent Systems by Potentiometric Measurements. J. Chem. Eng. Data 2004, 49, 1185−1188. (2) Deyhimi, F.; Karimzadeh, Z. Pitzer and Pitzer-Simonson-Clegg modeling approaches: Ternary HCl + 1-propanol plus water electrolyte system. Fluid Phase Equilib. 2010, 287, 155−160. (3) Deyhimi, F.; Salamat-Ahangari, R.; Karimzadeh, Z. Thermodynamic investigation of KCl in the ternary KCl/LiCl/H2O mixed electrolyte system based on potentiometric method. CALPHAD: Comput. Coupling Phase Diagrams Thermochem. 2007, 31, 522−528. (4) Deyhimi, F.; Salamat-Ahangari, R. Potentiometric investigation of the thermodynamic properties of the ternary mixed (NH4Cl + CaCl2 +H2O) electrolyte system. Fluid Phase Equilib. 2008, 264, 113−121. (5) Deyhimi, F.; Salamat-Ahangari, R.; Ghalami-Tchoobar, B. Determination of activity coefficients of NH4Cl in methanol-water mixed solvents at 25 °C by electromotive force measurements. Phys. Chem. Liq. 2003, 41, 605−611. (6) Deyhimi, F.; Ghalami-Choobar, B. Activity coefficients for NH4Cl in 2-PrOH/water mixed solvent and some thermodynamic correlations for NH4Cl in ROH/water mixed solvents (R = Me, Et, 1-Pr and 2-Pr). Fluid Phase Equilib. 2006, 246, 185−190. (7) Åkerlöf, G. Activity Coefficients of Sodium, Potassium, and Lithium Chlorides and Hydrochloric Acid at Infinite Dilution in Water−Methyl Alcohol Mixtures. J. Am. Chem. Soc. 1930, 52, 2353− 2368.

Table 4. Binary (χ(0), χ(1,0), and χ(1,1)) and Ternary (ξ and ω) Ion−CH3OH Interaction Parameters of the Modified Pitzer Equations for NaCl in Different Mass Fractions (x) of CH3OH in Water, at 298.15 K CH3OH (x)

χ(0)AMX

χ(1,0)AMX

χ(1,1)AMX

ξMXA

ωMXA

σ

0.10 0.20 0.30 0.40 0.50

−0.0037 0.0067 0.0071 −0.0056 0.0045

−0.1000 −0.1950 −0.1730 −0.1779 −0.1810

0.0485 0.0289 0.0228 0.0144 0.0063

0.0004 0.0096 0.0039 0.0051 −0.0014

−0.0003 −0.0047 −0.0049 −0.0018 −0.0007

6.88·10−3 3.03·10−3 4.54·10−3 2.36·10−3 1.44·10−3

328

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dx.doi.org/10.1021/je201084a | J. Chem. Eng.Data 2012, 57, 324−329